Multi-projection display

ABSTRACT

A multi projection display includes a plurality of projector units to modulate light from an LED light source according to image information to project, a unit image information generating unit to generate unit image information to be inputted to each of the plurality of projector units, and a unit image information correcting unit to correct the unit image information based on a result of capturing projection images projected onto a transmissive screen. For this reason, a shutter, which results in complicating the construction, is not needed and further it is possible to further reduce the adjustment time.

BACKGROUND OF THE INVENTION

1. Field of Invention

Exemplary aspects of the present invention relate to a multi-projectiondisplay.

2. Description of Related Art

A related art multi-projection display includes a plurality of projectorunits (projection optical unit) that are arranged in a horizontaldirection and in a vertical direction, and projection images from theplurality of projector units are projected onto a screen in a magnifiedscale to display one large screen image. For example, see JapaneseUnexamined Patent Application Publication No. 8-82854, JapaneseUnexamined Patent Application Publication No. 8-94974, JapaneseUnexamined Patent Application Publication No. 2001-339672, InternationalPublication Pamphlet No. 99/31877, Japanese Unexamined PatentApplication Publication No. 9-326981, Japanese Unexamined PatentApplication Publication No. 2001-251651, Japanese Unexamined PatentApplication Publication No. 6-178327, Japanese Unexamined PatentApplication Publication No. 9-211386, and U.S. Pat. No. 5,956,000. Sucha multi-projection display can display a high definition and highbrightness image, as compared to other related art projectors. Thus, itis expected that the multi-projection display will be widely used infuture in a business field, such as a cinema, an art gallery, a museum,a seminar hall, an assembly hall, a mini-theater, a public institute,and a company or in a domestic field, such as an amusement and a hometheater.

SUMMARY OF THE INVENTION

In these related art multi-projection displays, if the projection imagesfrom the respective projector units are not smoothly connected to eachother, it is impossible to match the projection images from therespective projector units. Further, a boundary is noticeable, and imagequality is lowered.

For this reason, in the related art multi-projection display disclosedin Japanese Unexamined Patent Application Publication No. 8-82854 andJapanese Unexamined Patent Application Publication No. 8-94974, in orderto address the above problem, the projection images from the respectiveprojector units are made not to overlap each other and the jointportions thereof become small.

However, in such related art multi-projection displays, there is aproblem in that at the time of setting up, it is not easy to removejoint portions of the projection images from the respective projectorunits or connect the projection images without inconsistency.

For this reason, in the related art multi-projection display disclosedin Japanese Unexamined Patent Application Publication No. 2001-339672,International Publication Pamphlet No. 99/31877, Japanese UnexaminedPatent Application Publication No. 9-326981, Japanese Unexamined PatentApplication Publication No. 2001-251651, Japanese Unexamined PatentApplication Publication No. 6-178327, Japanese Unexamined PatentApplication Publication No. 9-211386, and U.S. Pat. No. 5,956,000 inorder to address the above problem, the projection images from adjacentprojector units are made to overlap partially on the screen such thatthe projection images are smoothly connected to each other in theoverlapped region.

However, in such related art multi-projection displays, if the method ofdisplaying the projection images from the respective projector units onthe screen are not accurately known, it is impossible to smoothlyconnect the projection images on the screen. Thus, when the related artmulti-projection display disclosed in Japanese Unexamined PatentApplication Publication No. 2001-339672, International PublicationPamphlet No. 99/31877, Japanese Unexamined Patent ApplicationPublication No. 9-326981, and Japanese Unexamined Patent ApplicationPublication No. 2001-251651, is used with a watch camera or a digitalcamera, the projection images (Adjusting images) from the respectiveprojector units which are displayed on the screen are captured and canbe accurately measured.

In the related art multi-projection display using these image-capturingdevices, in order to perform the adjustment to match the projectionimages from the respective projector units, there is a need to preventinfluence of the projection image by an adjacent projector unit. Forthis reason, the capturing operation to the adjusting image needs to beperformed for every projector unit.

However, since a light emitting tube having high brightness and highcolor-rendering property, such as a high pressure mercury lamp or ametal halide lamp, is typically used as a light source of the projectorunit, after the light emitting tube is turned on, obtaining a stableemitting state takes a minimum of several minutes.

For this reason, in the related art multi-projection display disclosedin Japanese Unexamined Patent Application Publication No. 2001-339672,shutters are arranged in front of the projection lenses of therespective projector units and these shutters are allowed to suitablyoperate. Thus, in the multi-projection display, the capturing operationfor every projector unit is performed in a state in which the lightemitting tube is turned on, such that the adjustment operation isperformed in a few minutes.

However, in the related art multi-projection display disclosed inJapanese Unexamined Patent Application Publication No. 2001-339672, inorder to perform the adjustment to match the projection images from therespective projector units to each other, the shutter must be operatedmechanically for every projector unit. Thus, there are problems in thatthe system becomes complicated and the adjustment time is not easilyreduced.

Accordingly, exemplary aspects of the present invention are made toaddress and/or solve the above and/or other problems. Exemplary aspectsof the present invention provide a multi-projection display which canfurther shorten the adjustment time with no shutter required to matchprojection images from the respective projector units.

The present inventors have studied to attain the above and discoveredthat the above can be attained by using a solid-state light source as alight source of the multi-projection display and by performing anadjustment operation using light from the solid-state light source,thereby completing the present invention.

(1) A multi-projection display of an exemplary aspect of the presentinvention includes a plurality of projector units to modulate light froma solid-state light source based on image information, a unit imageinformation generating unit to generate image information (Hereinafter,“unit image information”) to be input to each of the plurality ofprojector units, and a unit image information correcting unit to correctthe unit image information based on a result of capturing projectionimages projected onto a screen.

For this reason, according to the multi-projection display of anexemplary aspect of the present invention, instead of a high pressuremercury lamp or a metal halide lamp which has high brightness, but takesseveral minutes until its emitting state is stable after being turnedon, a solid-state light source that acquires a stable emitting stateimmediately after turning on is used. Thus, it is possible todrastically shorten the time required to capture the projection imagesto be projected from the respective projector units onto the screen. Asa result, it is possible to drastically shorten the adjustment time tomatch the projection images from the respective projector units. Thusconvenience is largely enhanced.

Further, according to the multi-projection display of an exemplaryaspect of the present invention, the solid-state light source can befreely set to a turned-on state or a turned-off state. Thus it ispossible to remove the shutter which complicates the system. Since thesolid-state light source is in the stable emitting state immediatelyafter being turned on, it is possible to begin capturing at once.

(2) In the multi-projection display according to an exemplary aspect ofthe invention (1), the solid-state light source may be an LED lightsource, a semiconductor laser light source, a solid-state laser lightsource, or an EL light source.

Thus, a multi-projection display in which is easy to adjust since thestable turned-on state is acquired at once and which has sufficientbrightness and color-rendering property is acquired.

(3) In the multi-projection display according to exemplary aspects ofthe invention (1) or (2), the unit image information correcting unit maycorrect the unit image information based on a result of capturingadjusting unit images projected by the projector units.

The unit image information correcting unit may perform the correction ofthe unit image information based on a capturing result of a related artimage. However, by correcting the unit image information based on theresult of capturing the adjusting unit image, it is possible to performthe more accurate correction rapidly.

As the adjusting unit image, various unit images suitable to perform thecorrection of the unit image information, such as a beta image of whiteor monochrome, a lattice shape of monochrome, may be used.

In this case, it may be constructed such that the adjusting imageinformation is previously stored in the multi-projection display and theunit image information generating unit generates the adjusting unitimage using the adjusting image information at the time of theadjustment operation. In addition, the adjusting unit image informationmay be previously stored in the multi-projection display and at the timeof the adjustment operation, the adjusting unit image information may beused as it is.

Further, when the adjustment operation is performed, the adjusting imageinformation may be input to the multi-projection display (a DVD or thelike) and the unit image information generating unit may generate theadjusting unit image information using the adjusting image information.Further, when the adjustment operation is performed, the adjusting unitimage information may be input directly to the multi-projection display.

(4) In the multi-projection display according to any exemplary aspect ofthe invention (1) to (3), the unit image information correcting unit maycorrect shapes, positions and/or inclinations of unit images to beprojected by the projector units.

If doing so, the shapes, the positions and/or the inclinations of theprojection images from the respective projector units become proper.Thus it is possible to highly match the projection images from therespective projector units.

(5) In the multi-projection display according to any one of theexemplary aspects of the invention (1) to (3), the unit imageinformation correcting unit may correct the brightness and/or colors ofunit images to be projected by the projector units.

If doing so, the brightness and/or colors of the projection images fromthe respective projector units become proper. Thus it is possible tohighly match the projection images from the respective projector units.

(6) In the multi-projection display according to any one of theexemplary aspects of the invention (1) to (5), the unit imageinformation correcting unit may have a function of correcting thebrightness and/or color for every pixel in the plurality of projectorunits.

If doing so, it is possible to further match the projection images fromthe respective projector units, and thus it is possible to projectimages true to original image information.

In this case, the unit image information correcting unit may have afunction of correcting the unit image to the brightness and/or color forevery pixel in the respective projector units by comparing the adjustingimage, which is formed by a plurality of adjusting unit images to beprojected by the plurality of projector units, as a whole and anoriginal adjusting image.

(7) In the multi-projection display according to any one of theexemplary aspects of the invention (1) to (6), the display may includean image-capturing device for capturing the projection images projectedonto the screen.

If doing so, it is possible to shorten the time required for capturing.Thus it is possible to drastically shorten the adjustment operation timeto match the projection images from the respective projector units.

(8) In the multi-projection display according to any one of theexemplary aspects of the invention (1) to (7), the unit imageinformation correcting unit may correct the unit image information usingcorrection parameters that are determined based on the capturing result.

If doing so, after the correction parameters are determined once basedon the capturing result, it is possible to easily correct the unit imageinformation using the correction parameters.

(9) In the multi-projection display according to an exemplary aspect ofthe invention (8), the display may include a correction parameterstoring unit to store the correction parameters.

If doing so, it is possible to make the required storage capacitysmaller than when storing the capturing result itself. Further, it ispossible to make the calculation quantities, when correcting the unitimage information, small.

(10) In the multi-projection display according to exemplary aspects ofthe invention (8) or (9), the display may include a correction parameterautomatic acquiring device to capture an adjusting image in certaincircumstances to automatically acquire the correction parameters.

If doing so, for example, when the correction parameters are needed tobe determined again (Acquired again.) For example, three months lapseafter acquiring again), the correction parameter automatic acquiringdevice may operate automatically to acquire the correction parametersagain. Further, when a regular time comes (For example, at 4 a.m.), thecorrection parameter automatic acquiring device may operateautomatically to acquire the correction parameters again. Thus, withouttroubling the user, it is possible to maintain smooth image quality, andfurther convenience is enhanced.

Further, even though the characteristics of the light source or theelectro-optical modulating device are changed by variation per hour, thecorrection parameters corresponding to the change in characteristic canbe automatically acquired. Thus, it is possible to constantly suppressdeterioration of image quality due to the variation per hour.

(11) In the multi-projection display according to any one of theexemplary aspects of the invention (1) to (10), the display may includean optical correcting device to correct the position and/or orientationof an optical element provided in the multi-projection display.

If doing so, after the position and/or orientation of the opticalelement is corrected once, smooth image quality is acquired. Since thecorrection is optically performed, there is no deterioration of imagequality due to the adjustment operation.

In this case, after the optical correction to the position and/ororientation of the optical element is first performed, the capturing bythe image-capturing device may be performed again. Then the correctionparameters are determined based on the capturing result.

If doing so, after optically performing the large scale correctionfirst, it is possible to perform the minute correction purelyelectronically. Further, it is possible to suppress deterioration ofimage quality to be generated when the unit image information correctingunit corrects the unit image information to a minimum.

(12) In the multi-projection display according to exemplary aspect ofthe invention (11), the display may include an optical element automaticcorrecting device to capture an adjusting image in certain circumstancesto automatically correct the position and/or orientation of the opticalelement.

If doing so, for example, when the correction parameters are needed tobe determined again (Acquired again.) (For example, three months lapseafter acquiring again) or when the regular time comes every day (Forexample, at 4 a.m.), the correction parameter automatic acquiring devicemay operate automatically to correct the position and/or orientation ofthe optical element. Thus, without troubling the user, it is possible tomaintain smooth image quality, and further convenience is enhanced.

(13) In the multi-projection display according to any one of theexemplary aspects of the invention (1) to (12), the display may includea solid-state light source control unit to control the amount of lightemitted from the solid-state light source separately for every projectorunit.

In the multi-projection display, generally, due to unevenness incharacteristic in the light source or the electro-optical modulatingdevice, it is the present situation that a brightness characteristic ora color characteristic for every projector unit is different. For thisreason, in the multi-projection display, a voltage to be applied to theelectro-optical modulating device for every projector unit is adjustedsuch that the difference of the brightness characteristics or the colorcharacteristics is absorbed. As a result, in the multi-projectiondisplay, by performing the adjustment, the gradation source is needed tobe used in the electro-optical modulating device, which results inproblems in that the number of effective gradations inherent in themulti-projection display is lowered or the dynamic range becomes narrow.

According to the multi-projection display of an exemplary aspect of theinvention (13), by controlling the amount of light emitted from thesolid-state light source for every projector unit, it is possible toabsorb the difference of the brightness characteristics or the colorcharacteristics. For this reason, according to the multi-projectiondisplay of an exemplary aspect of the present invention, since there isno need to use the gradation source in the electro-optical modulatingdevice, there is no case in which the number of effective gradationsinherent in the multi-projection display is lowered or the dynamic rangebecomes narrow.

In this case, in order to absorb the difference of the brightnesscharacteristic for every projector unit, in the projector units otherthan the projector unit having the lowest brightness level, the amountof light emitted from the solid-state light source may be lowered suchthat the brightness level in the projector units complies with thebrightness level in the projector unit having the lowest brightnesslevel.

Further, in order to absorb the difference of the color characteristicfor every projector unit, the above-mentioned adjustment may beperformed for every color light component.

Moreover, in the multi-projection display of the exemplary aspect of theinvention (13), unlike a case in which the high pressure mercury lamp orthe metal halide lamp is used as the light source, while the amount ofemitted light decreases or increases as the voltage decreases orincrease, the color temperature is not almost changed. Thus, there is nodeterioration of image quality.

In the multi-projection display of the exemplary aspect of the invention(13), the solid-state light source control unit may have a function ofcontrolling separately the voltage to be supplied to the solid-statelight source for every projector unit.

If doing so, it is possible to easily increase or decrease the amount oflight emitted from the solid-state light source for every projectorunit.

In the multi-projection display of the exemplary aspect of the invention(13), the solid-state light source control unit may have a function ofcontrolling separately the pulse width of alternating current (AC) powerto be supplied to the solid-state light source for every projector unit.

If doing so, it is possible to easily increase or decrease the amount oflight emitted from the solid-state light source for every projectorunit.

(14) In the multi-projection display according to any one of theexemplary aspects of the invention (1) to (13), the multi-projectiondisplay may be a rear surface projection type multi-projection displaywhich may include a transmissive screen to project the projection imagesfrom the plurality of projector units.

In this case, since it is possible to drastically shorten theabove-mentioned adjustment time, it is possible to drastically shortenthe time required for an assembling operation when the multi-projectiondisplay is assembled into the housing. Thus, it is possible to easilyreduce the cost of the product. Further, when the maintenance of themulti-projection display is performed, it is possible to drasticallyshorten the time required for the maintenance operation. Thusconvenience of the user is enhanced.

Moreover, in this case, the image-capturing device may be arranged inthe housing of the multi-projection display.

If doing so, once if the image-capturing device is arranged surely inthe housing of the rear surface projection type multi-projectiondisplay, there is no need to put the image-capturing device in orderafter the adjustment operation is completed. Thus, there is no need toset up the image-capturing device again when the projection image iscaptured. As a result, the adjustment operation becomes easy and theadjustment time is also shortened. Further, there are advantages thatthe image-capturing element can be easily set up at an accurate positionto the transmissive screen, and the capturing of the projection imagecan be performed accurately and easily. In addition, there areadvantages that the overall control unit to process the capturing resultcan be easily housed in the housing and the multi-projection display canbe easily moved and set up.

(15) In the multi-projection display according to any one of theexemplary aspects of the invention (1) to (13), the multi-projectiondisplay may be a front surface projection type multi-projection displaywhich projects the projection images from the projector units onto afront surface thereof.

In this case, since it is possible to drastically shorten theabove-mentioned adjustment time, it becomes possible to drasticallyshorten the time required for the adjustment operation when themulti-projection display is set up.

The present inventors has discovered that by using the solid-state lightsource as the light source of the multi-projection display and byperforming the adjustment operation using light from the solid-statelight source, the above-mentioned and/or other advantages can beobtained. However, the present inventors has also discovered that byusing the solid-state light source as the light source of themulti-projection display and by controlling the amount of light emittedfrom the solid-state light source for every projector unit, otherexcellent advantages can be obtained.

(16) Another multi-projection display of an exemplary aspect of thepresent invention includes a plurality of projector units, each having asolid-state light source to generate a plurality of color lightcomponents, a plurality of electro-optical modulating devices tomodulate the plurality of color light components respectively, and aprojection optical system to project color light components modulated bythe plurality of electro-optical modulating devices, a unit imageinformation generating unit to generate unit image information to beinputted to the plurality of projector units respectively, and asolid-state light source control unit to control the amount of lightemitted from the solid-state light source for every projector unit.

For this reason, according to another multi-projection display of anexemplary aspect of the present invention, since it is possible tocontrol separately the amount of light emitted from the solid-statelight source for every projector unit, it is possible to absorb thedifference of the brightness characteristic or the color characteristicfor every projector unit by controlling the amount of light emitted fromthe solid-state light source. For this reason, since there is no need touse the gradation source in the electro-optical modulating device, thereis no case in which the number of effective gradations inherent in themulti-projection display is lowered or the dynamic range becomes narrow.

In this case, in order to absorb the difference of the brightnesscharacteristic for every projector unit, in the projector units otherthan the projector unit having the lowest brightness level, the amountof light emitted from the solid-state light source may be lowered suchthat the brightness level in the projector units complies with thebrightness level in the projector unit having the lowest brightnesslevel.

Moreover, in the multi-projection display of the exemplary aspect of theinvention (16), unlike a case in which the high pressure mercury lamp orthe metal halide lamp is used as the light source, while the amount ofemitted light decreases or increases as the voltage decreases orincrease, the color temperature is not almost changed. Thus, there is nodeterioration of image quality.

(17) In the multi-projection display according to the exemplary aspectof the invention (16), the solid-state light source control unit mayhave a function of controlling the amount of light emitted from thesolid-state light source for every electro-optical modulating device.

If doing so, it is also possible to absorb the difference of the colorcharacteristic for every projector unit.

(18) In the multi-projection display according to the exemplary aspectsof the invention (16) or (17), the solid-state light source control unitmay have a function of dynamically controlling the amount of lightemitted from the solid-state light source.

If doing so, in the case in which a totally dark screen is displayed(For example, a case in which a night scene in a movie is displayed),instead of or in addition to lowering the transmittance of theelectro-optical modulating device, by decreasing the amount of lightemitted from the solid-state light source, it is possible to make anentire screen dark. Further, in the case in which a totally brightscreen is displayed (For example, a case in which an outdoor scene inthe daytime in a movie is displayed), instead of or in addition toincreasing the transmittance of the electro-optical modulating device,by increasing the amount of light emitted from the solid-state lightsource, it is possible to make the entire screen bright. For thisreason, it is possible to increase the number of effective gradations orthe dynamic range, which results in a high image qualitymulti-projection display having an excellent black level.

In this case, if the solid-state light source control unit is allowed todynamically control the amount of light emitted from the solid-statelight source, when an image in which a bright screen and a dark screenexist in one screen is displayed, it is possible for themulti-projection display to exhibit the expression ability exceeding thenumber of effective gradation or the dynamic range inherent in themulti-projection display. In addition, it is possible to perform highimage quality display.

(19) In the multi-projection display according to any one of theexemplary aspects of the invention (16) to (18), the solid-state lightsource control unit may have a function of controlling a voltage to besupplied to the solid-state light source for every projector unit or forevery electro-optical modulating device.

If doing so, it is possible to easily decrease or increase the amount oflight emitted from the solid-state light source for every projector unitor for every electro-optical modulating device.

(20) In the multi-projection display according to any one of theexemplary aspects of the invention (16) to (18), the solid-state lightsource control unit may have a function of controlling an emittingperiod of the solid-state light source for every projector unit or forevery electro-optical modulating device.

If doing so, it is also possible to easily decrease or increase theamount of light emitted from the solid-state light source for everyprojector unit or for every electro-optical modulating device.

(21) In the multi-projection display according to the exemplary aspectof the invention (20), the electro-optical modulating device may be aliquid crystal device which writes one unit screen information twice ormore, and the solid-state light source control unit may have a functionof allowing the solid-state light source to emit during one frameoutside at least the first writing period of the liquid crystal device.

In the multi-projection display using the liquid crystal device as theelectro-optical modulating device, since the liquid crystal device is ahold type display device, unlike a case of a CRT of an impulse typedisplay device, there is a problem in that a smooth moving picturedisplay is not obtained due to a so-called tailing phenomenon (Asregards the tailing phenomenon, see “Image Quality of Moving PictureDisplay in a Hold Type Display” IEICE Technical Report, EID99-10, pages55 to 60 (1999-06)).

According to the multi-projection display of exemplary aspect of theinvention (21), by performing writing twice or more to one unit screeninformation, it is possible to make a flicker inconspicuous. Further, aliquid crystal device of a so-called n-time speed driving (Here, n is anatural number of 2 or more) is used and the solid-state light source isallowed to emit outside at least the first writing period of the liquidcrystal device. Thus, it becomes possible to project intermittently theprojection images onto the screen. For this reason, it is possible toalleviate the tailing phenomenon which is a defect of the hold typedisplay, and further it is possible to perform moving picture displaysmoothly with favorable quality.

Further, according to the multi-projection display of exemplary aspectof the invention (21), the solid-state light source is allowed to emitduring one frame outside the first writing period at which liquidcrystal molecules do not yet sufficiently response. Thus, there is alsoan advantage in that it is possible to further improve contrast in themulti-projection display.

(22) In the multi-projection display according to the exemplary aspectof the invention (20), the electro-optical modulating device may be aliquid crystal device which writes an image sequentially for everyscreen region, and the solid-state light source control unit may have afunction of allowing the solid-state light source to emit during oneframe outside the image writing periods of the liquid crystal device.

For this reason, according to the multi-projection display of theexemplary aspect of the invention (22), during one frame or the like, aliquid crystal device which is capable of making a flicker inconspicuousby writing sequentially images for every screen region is used, and thesolid-state light source is allowed to emit outside the image writingperiods of the liquid crystal device. Thus, it becomes possible toproject intermittently the projection images onto the screen. For thisreason, it is possible to alleviate the tailing phenomenon which is adefect of the hold type display, and further it is possible to performmoving picture display smoothly with favorable quality.

Further, according to the multi-projection display of the exemplaryaspect of the invention (22), the solid-state light source is allowed toemit outside the image writing periods. Thus, there is also an advantagein that it is possible to further enhance contrast in themulti-projection display.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A and 1B are schematics showing a construction of amulti-projection display according to a first exemplary embodiment;

FIG. 2 is a schematic showing a construction of a projector unit in themulti-projection display according to the first exemplary embodiment;

FIG. 3 is a schematic showing an outline of the multi-projection displayaccording to the first exemplary embodiment;

FIG. 4 is a schematic showing an outline of the multi-projection displayaccording to the first exemplary embodiment;

FIG. 5 is a schematic showing an outline of the multi-projection displayaccording to the first exemplary embodiment;

FIGS. 6(i)-6 iii are schematics illustrating advantages of themulti-projection display according to the first exemplary embodiment;

FIG. 7 is a schematic illustrating advantages of the multi-projectiondisplay according to the first exemplary embodiment;

FIG. 8 is a schematic illustrating advantages of the multi-projectiondisplay according to the first exemplary embodiment;

FIG. 9 is a schematic illustrating advantages of the multi-projectiondisplay according to the first exemplary embodiment;

FIG. 10 is a schematic illustrating advantages of the multi-projectiondisplay according to the first exemplary embodiment;

FIG. 11 is a schematic illustrating advantages of the multi-projectiondisplay according to the first exemplary embodiment;

FIGS. 12A to 12C are schematics illustrating advantages of themulti-projection display according to the first exemplary embodiment;

FIG. 13 is a schematic showing a construction of a multi-projectiondisplay according to a second exemplary embodiment;

FIGS. 14(i)-14(iii) are schematics illustrating advantages of themulti-projection display according to the second exemplary embodiment;

FIG. 15 is a schematic showing an outline of the multi-projectiondisplay according to a third exemplary embodiment;

FIGS. 16A and 16B are schematics illustrating advantages of themulti-projection display according to the third exemplary embodiment;

FIG. 17 is a schematic illustrating an outline of the multi-projectiondisplay according to a fourth exemplary embodiment;

FIGS. 18A and 18B are schematics illustrating advantages of themulti-projection display according to the fourth exemplary embodiment;

FIGS. 19A and 19B are schematics illustrating advantages of themulti-projection display according to a fifth exemplary embodiment;

FIGS. 20A and 20B are schematics illustrating advantages of themulti-projection display according to the fifth exemplary embodiment;

FIG. 21 is a schematic illustrating advantages of the multi-projectiondisplay according to a sixth exemplary embodiment;

FIGS. 22A to 22C are schematics illustrating operations of themulti-projection display according to a seventh exemplary embodiment;

FIGS. 23A and 23B are schematics illustrating operations of themulti-projection display according to an eighth exemplary embodiment;

FIG. 24 is a schematic illustrating a construction of themulti-projection display according to a ninth exemplary embodiment; and

FIGS. 25A and 25B are schematics illustrating a construction of themulti-projection display according to a tenth exemplary embodiment.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS First Exemplary Embodiment

FIGS. 1A and 1B are schematics showing a construction of amulti-projection display according to a first exemplary embodiment. FIG.1A is a cross-sectional view as viewed from a side and FIG. 1B is afront view. FIG. 2 is a schematic showing a construction of a projectorunit in the multi-projection display according to the first exemplaryembodiment. FIGS. 3 to 5 are block schematics showing an outline of themulti-projection display according to the first exemplary embodiment.

A multi-projection display 100 according to the first exemplaryembodiment is a rear surface projection type in which the projectionimages from four projector units 130 (In FIG. 1A, only two projectorunits are shown) arranged in a housing 102 are reflected by reflectingplates 104 to be projected onto a transmissive screen 108, as shown inFIG. 1B. As shown in FIG. 2, the respective projector units 130 includeLED light sources 132R, 132G, and 132B as a solid-state light source,three liquid crystal devices 134R, 134G, and 134B as an electro-opticalmodulating device, a cross dichroic prism 136 and a projection lens 138.Illumination light components from the LED light sources 132R, 132G, and132B are modulated by the liquid crystal devices 134R, 134G, and 134Bbased on unit image information A₁ to A_(n) (See FIG. 3) or adjustingunit image information B₁ to B_(n) (See FIG. 4) and are projected by theprojection lens 138.

The multi-projection display 100 according to the first exemplaryembodiment includes a control unit 110 having a unit image informationgenerating unit 120, a unit image information correcting unit 150, animage processing unit 146 and an optical correcting device 154, fourprojector units 130, an image-capturing device 140, a video signalreceiving unit 160, an adjusting image information storing unit 122 anda correction parameter storing unit 152, as shown in FIGS. 3 to 5.

The unit image information generating unit 120 has a function ofgenerating a plurality of unit image information A₁ to A_(n) based onoriginal image information A (see FIG. 3) and a function of generatingthe adjusting unit image information B₁ to B_(n) based on the adjustingimage information B (See FIG. 4).

The image-capturing device 140 includes an image-capturing element 142to capture a predetermined region of an adjusting image projected ontothe transmissive screen 108 and an AD converting element 144 to convertan analog signal from the image-capturing element 142 into a digitalsignal.

The image processing unit 146 has a function of comparing a resultobtained by performing an image processing on the result captured by theimage-capturing device 140 with the adjusting image information B tooutput the comparison result to the unit image information correctingunit 150.

The unit image information correcting unit 150 has a function ofcorrecting unit image information based on the capturing result by theimage-capturing device 140 such that a boundary between unit images tobe projected by adjacent projector units among the plurality ofprojector units 130 is not noticeable on the transmissive screen 108.Thus, corrected unit image information A_(1*) to A_(n*) are outputted tothe respective projector units 130 (See FIG. 5).

The correction parameter storing unit 152 has a function storingcorrection parameters to be used when the unit image informationcorrecting unit 150 corrects unit image information.

The adjusting image information storing unit 122 has a function ofstoring information regarding adjusting images which are objects to becaptured by the image-capturing device 140.

According to the multi-projection display 100 of the first exemplaryembodiment, since the LED light sources 132R, 132G, and 132B which canacquire a stable emitting state immediately after turning on, is used asa light source of the projector units 130, it is possible to drasticallyshorten the time required until the image-capturing device 140 capturesthe predetermined region of the adjusting image to be projected onto thetransmissive screen 108 for every projector unit 130. As a result, it ispossible to drastically shorten the adjustment operation time formatching the projection images from the respective projector units 130.Thus convenience is greatly enhanced.

Further, according to the multi-projection display 100 of the firstexemplary embodiment, since the LED light sources 132R, 132G, and 132Bcan be freely set to a turned-on state or a turned-off state, a shutterused in Japanese Unexamined Patent Application Publication No.2001-339672 is not needed. Since the LED light sources 132R, 132G, and132B are in the stable emitting state immediately after being turned on,it is possible to begin capturing at once. Further, no time is requiredto operate the shutter. Thus it is also possible to further shorten theadjustment time.

Further, according to the multi-projection display 100 of the firstexemplary embodiment, since the LED light sources 132R, 132G, and 132Bare used as the solid-state light source, in addition to the stableemitting state, the multi-projection display has sufficient brightnessand color-rendering property.

In the multi-projection display 100 according to the first exemplaryembodiment, as described above, the unit image information correctingunit 150 corrects unit image information based on the result ofcapturing the adjusting unit images.

The unit image information correcting unit 150 may correct unit imageinformation based on the result of capturing a general image. However,in the present exemplary embodiment, by correcting unit imageinformation based on the result of capturing the adjusting unit images,it is possible to correct more accurately and rapidly.

As the adjusting unit image, various unit images suitable to correct theunit image information, such as a beta image of white or monochrome, alattice shape of monochrome, may be used.

In this case, instead of previously storing the adjusting imageinformation in the adjusting image information storing unit 122 andgenerating the adjusting unit images by the unit image informationgenerating unit using the adjusting image information at the time of theadjustment operation, the adjusting unit image information may bepreviously stored and at the time of the adjustment operation, and theadjusting unit image information may be used as it is.

Further, when the adjustment operation is performed, the adjusting imageinformation may be input (By a DVD or the like) and the unit imageinformation generating unit may generate the adjusting unit imageinformation using the adjusting image information. Further, when theadjustment operation is performed, the adjusting unit image informationmay be directly input.

In the multi-projection display 100 according to the first exemplaryembodiment, the unit image information correcting unit 150 has afunction of correcting the shapes, the positions and/or the inclinationsof the unit images to be projected by the respective projector units130. For this reason, the shapes, the positions and/or the inclinationsbetween the projection images from the respective projector units 130become proper. Thus it is possible to highly match the projection imagesfrom the respective projector units 130.

In the multi-projection display 100 according to the first exemplaryembodiment, the unit image information correcting unit 150 has afunction of correcting the brightness and/or colors of the unit imagesto be projected by the respective projector units 130. For this reason,the brightness and/or colors between the projection images from therespective projector units 130 become proper. Thus it is possible tohighly match the projection images from the respective projector units130.

FIGS. 6 to 12 are schematics showing advantages of the multi-projectiondisplay according to the first exemplary embodiment.

With reference to FIGS. 3 to 12, how the multi-projection display 100according to the first exemplary embodiment may correct the shapes, thepositions and/or the inclinations between the projection images from therespective projector units 130 will be described. Further, how thebrightness and/or colors between the projection images from therespective projector units 130 may be corrected will be described.

Display State Before Correcting

A display state before correcting will be described.

Referring to FIG. 3, if original image information A is input from thevideo signal receiving unit 160 to the unit image information generatingunit 120, the unit image information generating unit 120 generates unitimage information A₁ to A_(n) based on original image information A. Therespective projector units 130 project the unit images corresponding tounit image information A₁ to A_(n) onto the transmissive screen 108.Therefore, on the transmissive screen 108, the projection imagesaccording to the respective unit images from the respective projectorunits 130 are projected. In this situation, since the multi-projectiondisplay 100 is in a state before correcting, the distorted projectionimages (I_(a0), I_(b0), I_(c0), I_(d0)) as shown in FIG. 6(i) areprojected.

First Adjustment Operation

(An Adjustment Operation to the Shapes, the Positions and/or theInclinations of the Unit Images by the Optical Correcting Unit 154)

The first adjustment operation will now be described.

Referring to FIG. 4, if adjusting image information B from the adjustingimage information storing unit 122 is input to the unit imageinformation generating unit 120, the unit image information generatingunit 120 generates adjusting unit image information B₁ to B_(n) based onadjusting image information B. The respective projector units 130project the unit images corresponding to adjusting unit imageinformation B₁ to B_(n) onto the transmissive screen 108. In thissituation, since the multi-projection display 100 is in a state beforecorrecting, similar to the above description, since the multi-projectiondisplay 100 is in a state before correcting, the distorted projectionimages (I_(a0), I_(b0), I_(c0), I_(d0)) as shown in FIG. 6(i) areprojected.

Next, with the image-capturing element 142 of the image-capturing device140, predetermined regions of the respective projection images (I_(a0),I_(b0), I_(c0), I_(d0)) relating to the adjusting images shown in FIG.6(i) are captured. And then, the optical correcting device 154 opticallycorrects the position and/or orientation of the housing of therespective projector units 130 based on the capturing result. Moreover,in exemplary aspects of the present invention, instead of the housing ofthe projector units 130, the position and/or orientation of theprojection lens 138 of each of the projector units 130 or each of thereflecting plates 104 may be optically corrected.

If adjusting image information B from the adjusting image informationstoring unit 122 is inputted to the unit image information generatingunit 120 again, the respective projector units 130 project the unitimages corresponding to adjusting unit image information B₁ to B_(n)onto the transmissive screen 108. In this situation, however, theposition and/or orientation of the housing of the respective projectorunits 130 are being corrected based on the previous capturing result inthe multi-projection display 100. Thus, on the transmissive screen 108,as shown in FIG. 6(ii), the projection images (I_(a1), I_(b1), I_(c1),I_(d1)) having reduced distortion are projected.

Second Adjustment Operation

(An Adjustment Operation to the Shapes, the Positions and/or theInclinations of the Unit Images by the Unit Image Information CorrectingUnit 150)

The second adjustment operation will now be described.

Next, with the image-capturing element 142 of the image-capturing device140, the respective projection images (I_(a1), I_(b1), I_(c1), I_(d1))according to the adjusting images shown in FIG. 6(ii) are captured.Then, based on the capturing result, the unit image informationcorrecting unit 150 determines the correction parameters to be used whenunit image information is corrected. Subsequently, the determinedcorrection parameters are stored in the correction parameter storingunit 152, and then, based on the correction parameters, a plurality ofunit image information are generated from original image information.

Thus, if original image information A is input from the video signalreceiving unit 160 to the unit image information generating unit 120,the unit image information generating unit 120 generates unit imageinformation based on original image information A. In this situation,since unit image information is corrected by the correction parameters,unit image information A_(1*) to A_(n*) are generated. Therefore, therespective projector units 130 project the unit images corresponding tounit image information A_(1*) to A_(n*) onto the transmissive screen108. In this situation, since the multi-projection display 100 isalready adjusted, as shown in FIG. 6(iii), the projection images(I_(a2), I_(b2), I_(c2), I_(d2)) from the respective projector units 130are aligned precisely.

Moreover, in the first adjustment operation and the second adjustmentoperation, for example, as shown in FIG. 7 (A case in which theinclinations between the respective unit images projected exist) or FIG.8 (A case in which the inclinations between the respective unit imagesprojected do not exist), the correction may be performed such thatreference lines of the adjusting images in adjacent two projector units130 comply with each other, or the operation may be executed such thatthe reference line of the adjusting image in one projector unit 130 iscaptured.

In both cases, it is needed to turn on only the light source in adjacenttwo projector units 130 or it is needed to turn on only the light sourcein one projector unit 130.

However, according to the multi-projection display 100 of the firstexemplary embodiment, since the LED light sources 132R, 132G, and 132Bwhich can acquire the stable emitting state immediately after turning onare used as the light source of the respective projector units 130, itis possible to drastically shorten the time required for theabove-mentioned adjustment operation.

Third Adjustment Operation

(An Adjustment Operation to Brightness and/or Colors of the Unit Imagesby the Unit Image Information Correcting Unit 150)

The third adjustment operation will now be described. For the purpose ofsimple description, an adjustment of an overlapped region in adjacenttwo projector units (Temporarily, referred to as PJU_(a) and PJU_(b))will be described.

First, as shown in FIG. 9, a weight function in the overlapped region isadded to a pixel value of unit image information such that theprojection images (I_(a2), I_(b2)) from the adjacent projector unitsPJU_(a) and PJU_(b) are connected smoothly to each other. In thissituation, as the weight function, as shown in FIG. 10, a weightfunction taking γ correction into consideration is used. By doing so, asshown in FIG. 11, the projection images from the adjacent projectorunits PJU_(a) and PJU_(b) are connected to each other. As a result, asshown in FIGS. 12A to 12C, the projection images from the adjacent twoprojector units are favorably synthesized and smoothly connected to eachother.

In the multi-projection display 100 according to the first exemplaryembodiment, when two unit image information are generated based onoriginal image information relating to an original image (FIG. 12A), theunit images (FIG. 12B) are generated such that they are smoothlyconnected to each other on the transmissive screen 108 (FIG. 12C). Thus,the projection images from the adjacent two projector units PJU_(a) andPJU_(b) are favorably synthesized and smoothly connected to each other.

In the multi-projection display 100 according to the first exemplaryembodiment, the unit image information correcting unit 150 has afunction of correcting the brightness and/or color for every pixel inthe plurality of projector units 130.

For this reason, it is possible to highly match the projection imagesfrom the respective projector units 130, and thus it is possible toproject an image extremely true to original image information onto thescreen.

In this case, the unit image information correcting unit 150 may have afunction of correcting the unit image to the brightness and/or color forevery pixel in the respective projector units 130 by comparing all ofthe adjusting image, which are formed by a plurality of adjusting unitimages to be projected by the plurality of projector units 130 with anoriginal adjusting image.

The multi-projection display 100 according to the first exemplaryembodiment may include a correction parameter automatic acquiring deviceto capture the adjusting image in certain circumstances to automaticallyacquire the correction parameters.

For this reason, for example, when the correction parameters need to bedetermined again (Acquired again. For example, three months lapse afteracquiring again), the correction parameter automatic acquiring devicemay operate automatically to acquire the correction parameters again.Further, when the regular time comes every day (For example, at 4 a.m.),the correction parameter automatic acquiring device may operateautomatically to acquire the correction parameters again. Thus, withouttroubling the user, it is possible to maintain smooth image quality, andfurther convenience is enhanced.

Further, even though the characteristics of the LED light sources 132R,132G, and 132B or the liquid crystal devices 134R, 134G, and 134B arechanged by variation per hour, the correction parameters correspondingto the change in characteristic can be automatically acquired. Thus, itis possible to constantly suppress deterioration of image quality due tothe variation per hour.

Second Exemplary Embodiment

FIG. 13 is a schematic showing a construction of a multi-projectiondisplay according to a second exemplary embodiment. FIG. 14 is aschematic illustrating advantages of the multi-projection displayaccording to the second exemplary embodiment.

The multi-projection display 200 according to the second exemplaryembodiment is constructed such that an optical axis of a projectionlight flux from each of the projector units 230 is orthogonal to thescreen surface of the transmissive screen 208, as shown in FIG. 13.

For this reason, the unit images from the respective projector units 230do not have trapezoidal distortion. As a result, advantages in themulti-projection display 200 according to the second exemplaryembodiment are as shown in FIG. 14, unlike FIG. 6 showing advantages inthe multi-projection display 100 according to the first exemplaryembodiment.

However, in the multi-projection display 200 according to the secondexemplary embodiment, since the LED light sources (not shown) which canacquire the stable emitting state immediately after turning on(instantly turned on) are used as the light source of the respectiveprojector units 230. Thus, it is possible to obtain the same advantagesas those of the multi-projection display 100 according to the firstexemplary embodiment.

Third Exemplary Embodiment

FIG. 15 is a block schematic showing an outline of a multi-projectiondisplay according to the third exemplary embodiment. FIGS. 16A and 16Bare schematics illustrating advantages of the multi-projection displayaccording to the third exemplary embodiment. FIG. 16A is a schematicshowing advantages in the case in which the unit image has trapezoidaldistortion, and FIG. 16B is a schematic showing advantages in the casein which the unit image does not have trapezoidal distortion.

As shown in FIG. 15, the multi-projection display 300 according to thethird exemplary embodiment has a construction of a control unitdifferent from the multi-projection displays 100 and 200 according tothe first exemplary embodiment and the second exemplary embodiment. Thatis, in the multi-projection display 300 according to the third exemplaryembodiment, the control unit 112 has a construction excluding theoptical correcting device 154 from the construction of the control unit110 in the multi-projection display 100 and 200 according to the firstexemplary embodiment and the second exemplary embodiment.

However, in the multi-projection display 300 according to the thirdexemplary embodiment, the LED light sources (not shown) which canacquire the stable emitting state immediately after turning on(instantly turned on) are used as the light source of the respectiveprojector units 130. Thus, it is possible to obtain the same advantagesas those of the multi-projection display 100 and 200 according to thefirst exemplary embodiment and the second exemplary embodiment.

Further, the multi-projection display 300 according to the thirdexemplary embodiment can correct the unit images without using theoptical correcting device. Thus, it is possible to simplify thestructure. Further, it has an advantage in that it is possible to reducedesign costs and enhance reliability. In particular, themulti-projection display 300 can be suitably used as a rear surfaceprojection type multi-projection display in which the projector unitsare fixedly arranged in the housing.

Moreover, in the multi-projection display 300 according to the thirdexemplary embodiment, the unit image information is corrected only bythe working of the unit image information correcting unit 150, withoutusing the optical correcting device. Thus, hereinafter, the adjustmentmethod will be described.

Display State Before Correcting

Referring to FIG. 15, if original image information A is inputted fromthe video signal receiving unit 160 to the unit image informationgenerating unit 120, the unit image information generating unit 120generates unit image information A₁ to A_(n) based on original imageinformation. The respective projector units 130 project the unit imagescorresponding to unit image information A₁ to A_(n) onto the screen.Therefore, on the screen, the projection images relating to therespective unit images from the respective projector units 130 areprojected. In this situation, since the multi-projection display 100 isin a state before correcting, the distorted projection images (I_(a0),I_(b0), I_(c0), I_(d0)) as shown in FIG. 16A are projected.

First Adjustment Operation

(An Adjustment Operation to the Shapes, the Positions and/or theInclinations of the Unit Images by the Unit Image Information CorrectingUnit 150)

The first adjustment operation will be described.

Next, if adjusting image information B is input from the adjusting imageinformation storing unit 122 to the unit image information generatingunit 120, the unit image information generating unit 120 generatesadjusting unit image information B₁ to B_(n) (not shown) based onadjusting image information B. The respective projector units 130project the unit images corresponding to adjusting unit imageinformation B₁ to B_(n) onto the screen. In this situation, since themulti-projection display 300 is in a state before correcting, similar tothe above description, the distorted projection images (I_(a0), I_(b0),I_(c0), I_(d0)), as shown in FIG. 16A, are projected.

Next, with the image-capturing element 142 of the image-capturing device140, the respective projection images (I_(a0), I_(b0), I_(c0), I_(d0))relating to the adjusting images shown in FIG. 16A are captured. Then,based on the capturing result, the unit image information correctingunit 150 determines the correction parameters to be used when unit imageinformation is corrected. Subsequently, the determined correctionparameters are stored in the correction parameter storing unit 152.Then, based on the correction parameters, a plurality of unit imageinformation are generated from original image information.

Thus, if original image information A is input from the video signalreceiving unit 160 to the unit image information generating unit 120,the unit image information generating unit 120 generates unit imageinformation based on original image information A. But in thissituation, since unit image information is corrected by the correctionparameters, unit image information A_(1*) to A_(n*) (not shown) aregenerated. Therefore, the respective projector units 130 project theunit images corresponding to unit image information A_(1*) to A_(n*)onto the screen. In this situation, since the multi-projection display300 is already adjusted, as shown in FIG. 16B, the projection images(I_(a2), I_(b2), I_(c2), I_(d2)) from the respective projector units 130are located precisely.

Second Adjustment Operation

(An Adjustment Operation to Brightness and/or Colors of the Unit Imagesby the Unit Image Information Correcting Unit 150)

The second adjustment operation will be described. For the purpose ofsimple description, an adjustment of an overlapped region in adjacenttwo projector units (Temporarily, referred to as PJU_(a) and PJU_(b))will be described.

First, as shown in FIG. 9, a weight function in the overlapped region isadded to a pixel value of unit image information such that theprojection images (I_(a2), I_(b2)) from the adjacent projector unitsPJU_(a) and PJU_(b) are smoothly connected to each other. In thissituation, as the weight function, as shown in FIG. 10, a weightfunction taking γ correction into consideration is used. By doing so, asshown in FIG. 11, the projection images from the adjacent projectorunits PJU_(a) and PJU_(b) are connected to each other. As a result, asshown in FIGS. 12A to 12C, the projection images from the adjacent twoprojector units are favorably synthesized and smoothly connected to eachother.

In the multi-projection display 300 according to the third exemplaryembodiment, when two unit image information is generated based onoriginal image information relating to an original image (FIG. 12A), theunit images (FIG. 12B) are generated such that they are smoothlyconnected to each other on the transmissive screen (FIG. 12C). Thus, theprojection images from the adjacent two projector units PJU_(a) andPJU_(b) are favorably synthesized and smoothly connected to each other.

Fourth Exemplary Embodiment

FIG. 17 is a schematic showing an outline of a multi-projection displayaccording to a fourth exemplary embodiment. FIGS. 18 and 19 areschematics illustrating advantages of the multi-projection displayaccording to the fourth exemplary embodiment. FIG. 18A shows a case inwhich the highest brightness level white display is made in an entirescreen of the multi-projection display according to the first exemplaryembodiment. FIG. 18B shows a case in which the highest brightness levelwhite display is made in an entire screen of the multi-projectiondisplay according to the fourth exemplary embodiment.

As shown in FIG. 17, the multi-projection display 400 according to thefourth exemplary embodiment may include a solid-state light sourcecontrol unit 170 to control the amount of emitted light of the LED lightsources 132R, 132G, and 132B for every projector unit 130, in additionto the construction of the multi-projection display 100 according to thefirst exemplary embodiment. The solid-state light source control unit170 has a function of controlling the amount of emitted light of the LEDlight sources 132R, 132G, and 132B for every liquid crystal device 134R,134G or 134B.

For this reason, the multi-projection display 400 according to thefourth exemplary embodiment has the following advantages, in addition tothe advantages in the multi-projection display 100 according to thefirst exemplary embodiment.

According to the multi-projection display 400 of the fourth exemplaryembodiment, as shown in FIG. 18B, it is possible to control separatelythe amount of emitted light of the LED light sources 132R, 132G, and132B for every projector unit 130. Thus, it is possible to absorb thedifference of the brightness characteristics or the colorcharacteristics for every projector unit 130 by controlling the amountof emitted light of the LED light sources 132R, 132G, and 132B. For thisreason, as shown in FIGS. 19A and 19B, there is no need to use thegradation source in the electro-optical modulating device 134R, 134G,and 134B. Thus, there is no case in which the number of effectivegradations inherent in the multi-projection display is lowered or thedynamic range becomes narrow.

Further, according to the multi-projection display 400 of the fourthexemplary embodiment, it is possible to control separately the amount ofemitted light of the LED light sources 132R, 132G, and 132B for everyliquid crystal device 134R, 134G or 134B. Thus, it is also possible toabsorb the difference of the brightness characteristics or the colorcharacteristics by controlling the amount of emitted light of the LEDlight sources 132R, 132G, and 132B.

In the multi-projection display 400 according to the fourth exemplaryembodiment, as shown in FIG. 18B, in order to absorb the difference ofthe brightness characteristic for every projector unit 130, in theprojector units (projector units projecting the unit images Ia, Ib andId) other than the projector unit having the lowest brightness level(projector unit projecting the unit image Ic), the amount of emittedlight of the LED light sources is lowered such that the brightness levelin the projector units complies with the brightness level in theprojector unit having the lowest brightness level.

In the multi-projection display 400 according to the fourth exemplaryembodiment, the amount of emitted light of the LED light sources iscontrolled for every color light component.

In the multi-projection display 400 according to the fourth exemplaryembodiment, the solid-state light source control unit 170 may separatelycontrol voltages to be supplied to the LED light sources 132R, 132G, and132B or may separately control the emitting periods of the LED lightsources 132R, 132G, and 132B, for every projector unit 130 and/or forevery liquid crystal device 134R, 134G or 134B. In any cases, it ispossible to easily decrease or increase brightness of the LED lightsources 132R, 132G, and 132B.

Fifth Exemplary Embodiment

FIGS. 20A and 20B are schematics illustrating advantages of amulti-projection display according to a fifth exemplary embodiment.

The multi-projection display 500 (not shown) according to the fifthexemplary embodiment includes the solid-state light source control unit172 (not shown) to control the amount of emitted light of the LED lightsources 132R, 132G, and 132B for every projector unit 130, similar tothe multi-projection display 400 according to the fourth exemplaryembodiment. Further, the solid-state light source control unit 172 has afunction of controlling the amount of emitted light of the LED lightsources 132R, 132G, and 132B for every liquid crystal device 134R, 134Gor 134B, similar to the multi-projection display 400 according to thefourth exemplary embodiment.

In the multi-projection display 500 according to the fifth exemplaryembodiment, the solid-state light source control unit 172 also has afunction of dynamically controlling the amount of emitted light of theLED light sources 132R, 132G, and 132B, in addition to theabove-mentioned function.

For this reason, the multi-projection display 500 according to the fifthexemplary embodiment has the following advantages, in addition to theadvantages in the multi-projection display 400 according to the fourthexemplary embodiment.

As shown in FIG. 20B, in the case in which a totally dark screen isdisplayed (for example, a case in which a night scene in a movie isdisplayed), instead of or in addition to lowering the transmittance ofthe liquid crystal devices 134R, 134G, and 134B, by decreasing theamount of emitted light of the LED light sources 132R, 132G, and 132B,it is possible to make an entire screen dark. Further, as shown in FIG.20A, in the case in which a totally bright screen is displayed (forexample, a case in which an outdoor scene in the daytime in a movie isdisplayed), instead of or in addition to increasing the transmittance ofthe liquid crystal devices 134R, 134G, and 134B, by increasing theamount of emitted light of the LED light sources 132R, 132G, and 132B,it is possible to make the entire screen bright.

For this reason, it is possible to increase the number of effectivegradations or the dynamic range, which results in a high image qualitymulti-projection display having an excellent black level.

Sixth Exemplary Embodiment

FIG. 21 is a schematic illustrating advantages of a multi-projectiondisplay according to a sixth exemplary embodiment.

The multi-projection display 600 (not shown) according to the sixthexemplary embodiment includes the solid-state light source control unit174 (not shown) to control the amount of emitted light of the LED lightsources 132R, 132G, and 132B for every projector unit 130 and for everyliquid crystal device 134R, 134G or 134B, similar to themulti-projection display 500 according to the fifth exemplaryembodiment. Further, the solid-state light source control unit 174 alsohas a function of dynamically controlling the amount of emitted light ofthe LED light sources 132R, 132G, and 132B, similarly to themulti-projection display 500 according to the fifth exemplaryembodiment.

In the multi-projection display 600 according to the sixth exemplaryembodiment, the solid-state light source control unit 174 also has afunction of dynamically controlling the amount of emitted light of theLED light sources 132R, 132G, and 132B for every projector unit 130, inaddition to the above-mentioned function.

For this reason, the multi-projection display 600 according to the sixthexemplary embodiment has the following advantages, in addition to theadvantages in the multi-projection display 500 according to the fifthexemplary embodiment.

That is, as shown in FIG. 21, in the case in which an image in which abright screen and a dark screen exist in one screen is displayed, it ispossible for the multi-projection display to exhibit the expressionability exceeding the number of effective gradation or the dynamic rangeinherent in the multi-projection display. In addition, it is possible toperform high image quality display.

Seventh Exemplary Embodiment

A multi-projection display 700 (not shown) according to the seventhexemplary embodiment includes the solid-state light source control unit176 (not shown) to control the amount of emitted light of the LED lightsources 132R, 132G, and 132B for every projector unit 130 and for everyliquid crystal device 134R, 134G or 134B, similar to themulti-projection display 600 according to the sixth exemplaryembodiment. Further, the solid-state light source control unit 176 alsohas a function of dynamically controlling the amount of emitted light ofthe LED light sources 132R, 132G, and 132B for every projector unit 130.

The multi-projection display 700 according to the seventh exemplaryembodiment includes the liquid crystal devices 134R, 134G, and 134B (notshown), which perform writing twice or more to one unit imageinformation, as the liquid crystal device. Further, in themulti-projection display 700 according to the seventh exemplaryembodiment, the solid-state light source control unit 176 has a functionof allowing the solid-state light source to emit during one frameoutside at least the first writing period of the liquid crystal devices134R, 134G, and 134B.

FIGS. 22A to 22C are schematics illustrating operations of themulti-projection display according to the seventh exemplary embodiment.FIG. 22A shows a two-time speed driving liquid crystal device, FIG. 22Bshows a three-time speed driving liquid crystal device, and FIG. 22Cshows a four-time speed driving liquid crystal device.

According to the multi-projection display 700 of the seventh exemplaryembodiment, as shown in FIGS. 22A to 22C, writing is performed twice ormore to one unit screen information, and a liquid crystal device of aso-called n-time speed driving (here, n is a natural number of 2 ormore) is used. Further, the solid-state light source is allowed to emitoutside at least the first writing period of the liquid crystal device.Thus, it becomes possible to project intermittently the projectionimages onto the screen. For this reason, it is possible to alleviate thetailing phenomenon which is a defect of the hold type display, andfurther it is possible to perform moving picture display smoothly withfavorable quality.

Further, in the first writing period, since the liquid crystal moleculesdo not yet sufficiently respond, it is not easy to raise contrast of theliquid crystal device. However, according to the multi-projectiondisplay 700 of the seventh exemplary embodiment, since the solid-statelight source is allowed to emit outside the first writing period, in theliquid crystal device and the multi-projection display, it has anadvantage that it is possible to further enhance contrast.

Eighth Exemplary Embodiment

FIGS. 23A and 23B are schematics showing operations of amulti-projection display according to an eighth exemplary embodiment.The multi-projection display 800 (not shown) according to the eighthexemplary embodiment includes the solid-state light source control unit178 (not shown) to control the amount of emitted light of the LED lightsources 132R, 132G, and 132B for every projector unit 130 or for everyliquid crystal device 134R, 134G or 134B, similarly to themulti-projection display 600 according to the sixth exemplaryembodiment. Further, the solid-state light source control unit 178 has afunction of dynamically controlling the amount of emitted light of theLED light sources 132R, 132G, and 132B for every projector unit 130.

The multi-projection display 800 according to the eighth exemplaryembodiment includes the liquid crystal devices 134R, 134G, and 134B,which perform image writing sequentially for every screen region duringone frame, as the liquid crystal device. Further, in themulti-projection display 800 according to the eighth exemplaryembodiment, the solid-state light source control unit 178 has a functionof allowing the LED light sources 132R, 132G, and 132B to emit duringone frame outside the image writing periods of the liquid crystaldevices 134R, 134G, and 134B.

For this reason, according to the multi-projection display 800 of theeighth exemplary embodiment, the LED light sources 132R, 132G, and 132Bare allowed to emit outside the image writing periods of the liquidcrystal devices 134R, 134G, and 134B. Thus, it has an advantage that itis possible to further improve contrast in the multi-projection display.

Ninth Exemplary Embodiment

FIG. 24 is a schematic showing a construction of a multi-projectiondisplay according to a ninth exemplary embodiment.

As shown in FIG. 24, the multi-projection display 900 according to theninth exemplary embodiment is a front surface projection typemulti-projection display. However, since the LED light sources (notshown) which can acquire the stable emitting state immediately afterbeing turned on are used as the light source of the respective projectorunits 930, it is possible to obtain the same advantages as those of themulti-projection display 100 according to the first exemplaryembodiment.

Tenth Exemplary Embodiment

FIGS. 25A and 25B are schematics showing a construction of amulti-projection display according to a tenth exemplary embodiment. FIG.25A is a cross-sectional view as viewed from a side, and FIG. 25B is afront view.

The multi-projection display 1000 according to the tenth exemplaryembodiment has almost the same construction as that of themulti-projection display 100 according to the first exemplaryembodiment, but, as shown in FIGS. 25A and 25B, it is different from themulti-projection display 100 according to the first exemplary embodimentin that the image-capturing element 142 in the image-capturing device isarranged in the housing 102 of the multi-projection display 1000.

For this reason, the multi-projection display 1000 of the tenthexemplary embodiment has the following advantages, in addition to theadvantages in the multi-projection display 100 according to the firstexemplary embodiment.

If the image-capturing device is arranged surely in the housing 102 ofthe multi-projection display 1000, there is no need to put theimage-capturing device in order after the adjustment operation iscompleted. Thus, there is no need to set up the image-capturing deviceagain every time the projection image is captured. As a result, theadjustment operation becomes easy and the adjustment time is alsoshortened.

Further, there are advantages that the image-capturing element 142 canbe easily set up at an accurate position to the transmissive screen 108,and the capturing of the projection image can be performed accuratelyand easily.

In addition, there are advantages that the overall control unit forprocessing the capturing result can be easily housed in the housing 102and the multi-projection display 1000 can be easily moved and set up.

The multi-projection display of exemplary aspects of the presentinvention is described based on the above-mentioned respective exemplaryembodiments. But the present invention is not limited to theabove-mentioned respective exemplary embodiments, and it may be realizedin various aspects within a scope without departing from the subjectmatter of the present invention. For example, the followingmodifications are possible.

(1) The multi-projection displays 100 to 1000 of the above-mentionedrespective exemplary embodiments use the LED light source as thesolid-state light source, but the present invention is not limited tothe LED light source, for example. Instead of the LED light source, forexample, a semiconductor laser light source, a solid-state laser lightsource, or an EL light source may be used.

Even in the case of using these solid-state light sources, it is easy toadjust since the stable emitting state is acquired at once. Further, itis possible to obtain the multi-projection display having sufficientbrightness and color-rendering property.

(2) The multi-projection displays 100 to 1000 of the above-mentionedrespective exemplary embodiments use a transmissive liquid crystaldevice as the electro-optical modulating device. But the presentinvention is not limited to the transmissive liquid crystal device.Instead of the transmissive liquid crystal device, for example, areflective liquid crystal device or a micromirror type opticalmodulating device may be used.

Even in the case of using these electro-optical modulating devices,similarly, it is possible to obtain the above-mentioned advantages ofthe present invention.

1. A multi-projection display, comprising: a plurality of projectorunits to modulate light from a solid-state light source based on imageinformation; a unit image information generating unit to generate unitimage information to be input to each of the plurality of projectorunits; and a unit image information correcting unit to correct the unitimage information based on a result concerning capturing projectionimages projected onto a screen.
 2. The multi-projection displayaccording to claim 1, the solid-state light source being an LED lightsource, a semiconductor laser light source, a solid-state laser lightsource, or an EL light source.
 3. The multi-projection display accordingto claim 1, the unit image information correcting unit correcting theunit image information based on the result of capturing adjusting unitimages projected by the projector units.
 4. The multi-projection displayaccording to claim 1, the unit image information correcting unitcorrecting shapes, positions and/or inclinations of the unit images tobe projected by the projector units.
 5. The multi-projection displayaccording to claim 1, the unit image information correcting unitcorrecting brightness and/or colors of the unit images to be projectedby the projector units.
 6. The multi-projection display according toclaim 1, the unit image information correcting unit having a function ofcorrecting brightness and/or color for every pixel in the plurality ofprojector units.
 7. The multi-projection display according to claim 1,further comprising: an image-capturing device to capture the projectionimages projected onto the screen.
 8. The multi-projection displayaccording to claim 1, the unit image information correcting unitcorrecting the unit image information using correction parameters thatare determined based on the capturing result.
 9. The multi-projectiondisplay according to claim 8, further comprising: a correction parameterstoring unit to store the correction parameters.
 10. Themulti-projection display according to claim 8, further comprising: acorrection parameter automatic acquiring device to capture an adjustingimage in certain circumstances to automatically acquire the correctionparameters.
 11. The multi-projection display according to claim 1,further comprising: an optical correcting device to correct the positionand/or orientation of an optical element provided in themulti-projection display.
 12. The multi-projection display according toclaim 11, further comprising: an optical element automatic correctingdevice to capture an adjusting image in certain circumstances toautomatically correct a position and/or orientation of the opticalelement.
 13. The multi-projection display according to claim 1, furthercomprising: a solid-state light source control unit to control an amountof light emitted from the solid-state light source separately for everyprojector unit.
 14. The multi-projection display according to claim 1,the multi-projection display being a rear surface projection typemulti-projection display which further comprises a transmissive screento project the projection images from the plurality of projector units.15. The multi-projection display according to claim 1, themulti-projection display being a front surface projection typemulti-projection display which projects the projection images from theprojector units onto a front surface thereof.
 16. A multi-projectiondisplay, comprising: a plurality of projector units, each having asolid-state light source to generate a plurality of color lightcomponents; a plurality of electro-optical modulating devices tomodulate the plurality of color light components respectively; and aprojection optical system to project color light components modulated bythe plurality of electro-optical modulating devices; a unit imageinformation generating unit to generate unit image information to beinput to the plurality of projector units respectively; and asolid-state light source control unit to control an amount of lightemitted from the solid-state light source for every projector unit. 17.The multi-projection display according to claim 16, the solid-statelight source control unit having a function of controlling the amount oflight emitted from the solid-state light source for everyelectro-optical modulating device.
 18. The multi-projection displayaccording to claim 16, the solid-state light source control unit havinga function of dynamically controlling the amount of light emitted fromthe solid-state light source.
 19. The multi-projection display accordingto claim 16, the solid-state light source control unit having a functionof controlling a voltage to be supplied to the solid-state light sourcefor every projector unit or for every electro-optical modulating device.20. The multi-projection display according to claim 16, the solid-statelight source control unit having a function of controlling an emittingperiod of the solid-state light source for every projector unit or forevery electro-optical modulating device.
 21. The multi-projectiondisplay according to claim 20, the electro-optical modulating devicebeing a liquid crystal device which writes one unit screen informationtwice or more, and the solid-state light source control unit having afunction of allowing the solid-state light source to emit during oneframe outside at least the first writing period of the liquid crystaldevice.
 22. The multi-projection display according to claim 20, theelectro-optical modulating device being a liquid crystal device whichwrites an image sequentially for every screen region, and thesolid-state light source control unit having a function of allowing thesolid-state light source to emit during one frame outside the imagewriting period of the liquid crystal device.